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0 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
INSTITUTE FOR NEUTRON PHYSICS AND REACTOR TECHNOLOGY (INR)
Model-based Generation of Neutron Induced Fission Yieldsup to 20 MeV by the GEF Code
K. Kern∗, M. Becker, C. Broeders, R. Stieglitz
∗Corresponding author: [email protected]
KIT – University of the State of Baden-Wuerttemberg andNational Research Center of the Helmholtz Association www.kit.edu
Outline
1 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Introduction
Modelling of pre-fission processes
Modelling of fission product yields
Results
Conclusions
Outline
2 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Introduction
Modelling of pre-fission processes
Modelling of fission product yields
Results
Conclusions
IntroductionMotivation
3 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Evaluated fission product distributions (JEFF 3.1) do not show a pronouncedproton-even-odd effect
Fission product distributions are given for maximum 3 energy intervals:
thermal − 400 keV400 keV − 14 MeV14 MeV − ?
Investigation of spectral effects of energy-dependent fission product yields in coupledcriticality/depletion calculations (providing distributions in multi-energy-group representation)
Model-based assessment of data uncertainties and covariances, of which the latter are notyet available in existing evaluated fission yields data libraries.
Outline
4 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Introduction
Modelling of pre-fission processes
Modelling of fission product yields
Results
Conclusions
Modelling of pre-fission processesApplied nuclear reaction models
5 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
A model description is needed not only for the fission process, but also for the formation of theexcited fissioning nucleus. The TALYS-1.4 code has been applied for this purpose. It should benoted that:
For a given target and incident neutron energy, TALYS calculates the probability for thefissioning nucleus to have proton and mass numbers Z and A, excitation energy E∗ andspin/parity Jπ .
At incident neutron energies lower than the fission barrier of the target, the fission processis unlikely to be preceded by any nucleon emission (first-chance fission).
At higher energies there is significant emission of nucleons, above all neutrons, before thenucleus undergoes fission (multi-chance fission).
In any case, the excited nucleus may emit gamma quanta before it undergoes fission.
Below the (n,nf) second-chance fission threshold, fission is dominated by the direct (n,f)process, whereas in 235U(n,F) there is also a (n,γf) contribution of roughly 10%. Sensitivities ofmodelled fission yields related to TALYS parameters thus show up mainly above the (n,nf)threshold.
Modelling of pre-fission processesApplied nuclear reaction models
6 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Summary of the essential models applied in the work with TALYS-1.4:
Initial formation of the excited nucleus is described by optical model calculation withdeformed potential from Soukhovitskiy using Coupled Channels partial wave expansion(CC) and Distorted Wave Born Approximation (DWBA), from which transmission coefficientsand scattering/absorption cross-sections are obtained.For pre-equilibrium processes, i. e. decay reactions before the nucleus reaches statisticalequilibrium, the exciton model and phenomenological descriptions are applied.Decay of an excited (equilibrated) compound nucleus is described by the Hauser-Feshbachformalism, which is very important for this work.
In this work, fission has been treated within the Hauser-Feshbach formalism and considered asa single-mode process by TALYS-1.4, which is the state-of-the-art method of fissioncross-section modelling. Fission transmission coefficients have been calculated based on theHill-Wheeler formula (here shown for a single-humped barrier):
PF (E∗ − ε) =1
1 + exp(− 2π(E∗−EF )
h̄ωF
)TF (E∗, Jπ) = ∑
iPF (E∗ − ε i ) +
∫ E∗
εcdε ρF (ε, Jπ) · PF (E∗ − ε)
Modelling of pre-fission processesFission reactions
7 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Figure 1: Below 5 MeV only first chance fission (solid red line), binary (n,f) reactions (dotted redline) dominating, pre-fission gamma emission (dashed red line) factor 10 smaller. Second (greenline) and third chance fission (pink line) are very important above their respective thresholds.
Outline
8 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Introduction
Modelling of pre-fission processes
Modelling of fission product yields
Results
Conclusions
Modelling of fission product yieldsApplied nuclear reaction model
9 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
In the frame of physical constraints and arguments, the GEF model uses empirical descriptionsfor a number of effects. This way, it provides a realistic reproduction not only of the yields offission fragments, but also of their initial excitation energy and spin as well as their deexcitation.Several important principles are applied in the modelling of fission fragment formation:
Inertia of degrees of freedom: Known from theoretical calculations to be high for fragmentmass numbers, but low for N/Z ratio. Hence, mass numbers assumed to be fixed at outerfission barrier during fission process, but N/Z later at scission point.
Separability principle: Nascent fragments determine microscopic potential (shell andpairing effects) of fissioning nucleus, which interplays with the macroscopic potential.Corroborated by two-center shell model calculations of Mosel and Schmitt [].
Energy sorting mechanism: Nascent fragments assumed to have not only their ownmicroscopic potential, but also their own intrinsic temperature. This affects the division ofintrinsic excitation energy among the fragments and gives an explanation of experimentalobservations.
Phenomenological description for the central values and variances of fragment yielddistribution with respect to fragment mass number and N/Z ratio.
Modelling of fission product yieldsApplied nuclear reaction model
10 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
The formation of fission fragments and their deexcitation is treated in the following way:
Multi-mode fission model: Weights of fission modes are determined from ratios ofHill-Wheeler transmission coefficients for the respective outer fission barrier. Resultdepends on Z , A and E∗ of fissioning nucleus.
Fission fragment formation is calculated for each fission mode;Z , A, E∗ and mean J of fragments are determined.
GEF uses the Weisskopf-Ewing formalism for fragment deexcitation, i. e. the impact offragment spins is neglected at first. Spin J of fragments only affects population of isomericstates in GEF model.
Fragments are assumed to deexcite by neutron and E1 gamma emissions until E∗
reaches the yrast line.
Subsequent gamma emissions down to the ground or isomeric state are assumed to be E2transitions.
Modelling of fission product yieldsCalculation of fission yields and covariance matrix
11 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
GEF fission yields have been generated in a Monte Carlo calculation for each bin of the fissioncontribution obtained from TALYS, setting the statistics of each bin in Z , A, E∗ and J of thecompound nucleus proportional to the calculated probability. The covariance matrix of FY has inturn been determined in a second run divided into N = 224 calculation steps with perturbedmodel parameters:
Vij =1N
·N
∑k=1
(yi,k − y i ) ·(yj,k − y j
)Total number of fission events in each calculation: 5 · 107, thus the statistical uncertaintiesof most yields are negligible compared to impacts of model parameter uncertainties.
GEF propagates estimated, uncorrelated parameter uncertainties.
Parent independent yields and their uncertainties have been obtained from GEF.
In calculation of parent cumulative yields and their uncertainties, covariances ofindependent yields and decay data have still been neglected.
Outline
12 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Introduction
Modelling of pre-fission processes
Modelling of fission product yields
Results
Conclusions
ResultsParent independent yields - thermal neutrons
13 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Figure 2: Independent fission product yields from 235U(n,F) induced by thermal neutrons. Resultsfrom GEF-2012/2.3 (still without uncertainty assessment) and GEF-2013/2.2 compared to EXFOR
ResultsParent cumulative yields - thermal neutrons
14 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Figure 3: Cumulative fission product yields from 235U(n,F) induced by thermal neutrons, calculatedfrom independent yields using ENDF/B-VII.1 decay data library. GEF results compared to EXFOR
ResultsParent cumulative yields - high energetic neutrons
15 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Figure 4: Cumulative fission product yields from 235U(n,F) induced by 14.7 MeV neutrons.Significant underestimation of FPY from the superlong mode around A = 115.
ResultsMeasuring the quality of model results
16 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
To measure the quality of the calculated fission product yields and their uncertainties, two testquantities H and H̃ have been calculated, corresponding to a reduced-χ2 test:
H =
√√√√√ 1N
·N
∑i=1
(yexp
i − ycalci)2
σ2yexp
i
H̃ =
√√√√√ 1N
·N
∑i=1
(yexp
i − ycalci)2
σ2yexp
i+ σ2
ycalci
The following values were obtained:
Table 1: Values of N, H and H̃ for Figures 2-4.
Figure N H, H̃ H H H̃1σ confidence interval GEF-2012/2.3 GEF-2013/2.2 GEF-2013/2.2
2 60 0.913 - 1.097 4.52 3.50 1.123 51 0.906 - 1.106 5.10 3.98 1.264 69 0.919 - 1.090 21.97 20.83 11.20
ResultsFission yields correlation matrix
17 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Figure 5: Plot of correlation matrix of fission product yields for 235 U(n,F) induced by thermalneutrons. Yields given as a function of proton number, mass number and isomer (left) or only as afunction of mass number (right). Visible anticorrelations originate from proton even-odd effect andcompetition between fission channels.
Outline
18 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Introduction
Modelling of pre-fission processes
Modelling of fission product yields
Results
Conclusions
Conclusions
19 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
General improvement of FPY modelling with switch from GEF-2012/2.3 to GEF-2013/2.2.
Realistic estimation of FPY uncertainties for parent independent FPY from 235U(n,F)induced by thermal neutrons.
Underestimation of FPY uncertainties for parent cumulative FPY from 235U(n,F) induced bythermal neutrons, which might be resolved by consideration of independent FPY and decaydata covariances.
Deviation in 14.7 MeV cumulative FPY in Figure 4 should be resolved by adjustment offission barrier parameters for superlong mode in GEF. The weight of this mode is a verysensitive quantity.
Still room for improvement of FPY modelling, as also shown by the values of H in Table 1.
Inconsistency between models of TALYS-1.4 and GEF: Single-mode fission vs. multi-modefission; multi-mode fission should already be considered in calculation of fission contributionas it is possible e. g. with the EMPIRE-3.2 code; parameters of coupled codes should beidentical. However, this would significantly increase the number of model parameters to befitted for fission cross-section calculations.
20 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Backup
Multichannel fission of Pu-241
21 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Potential energy of Fm-258
22 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT
Proton Even-Odd effect
23 Oct. 2, 2014 K. Kern - Model-based Generation of Neutron Induced Fission Yields up to 20 MeV by the GEF Code
KIT